Title :
In-Plane Silicon-On-Nothing Nanometer-Scale Resonant Suspended Gate MOSFET for In-IC Integration Perspectives
Author :
Durand, C. ; Casset, F. ; Renaux, P. ; Abelé, N. ; Legrand, B. ; Renaud, D. ; Ollier, E. ; Ancey, P. ; Ionescu, A.M. ; Buchaillot, L.
Author_Institution :
STMicroelectron., Crolles
fDate :
5/1/2008 12:00:00 AM
Abstract :
A 14-MHz in-plane nanoelectromechanical resonator based on a resonant-suspended-gate (RSG) MOSFET principle and integrated in a front-end process is demonstrated. The devices are in-plane flexural vibration mode beams (L = 10 mum, w = 165 nm, and h = 400 nm) with 120-nm gaps. This letter details the design and process flow fabrication steps. Then, the electrical device characteristics are demonstrated, comprising static and dynamic studies around the resonant frequency. Devices enable the comparison of a pure capacitive detection with the RSG-MOSFET-based detection on the same component, showing a 4.3-dB-huge peak. Due to its output signal amplification and in-IC integration potentialities, the RSG-MOSFET-based detection is ideal for any type of nanoelectromechanical structure displacement detection.
Keywords :
MOSFET; nanotechnology; resonators; frequency 14 MHz; front-end process; in-IC integration; in-plane flexural vibration mode beams; in-plane nanoelectromechanical resonator; in-plane silicon-on-nothing nanometer-scale MOSFET; nanoelectromechanical structure displacement detection; process flow fabrication; resonant suspended gate MOSFET; size 10 mum; size 165 nm; size 400 nm; In-IC integration; in-plane resonator; nanometer-scale resonator; resonant suspended gate (RSG) MOSFET; silicon on nothing (SON);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2008.919781
